DE19811851A1 - Fire fighting nitrogen generator for closed room oxygen concentration reduction, to halt combustion - Google Patents

Abstract

A nitrogen generator (as opposed to bottled gas) is used to reduce the oxygen concentration from the normal 21% to about 16% so that the room could still be visited safely. In case of fire this concentration is lowered to about 12% by using bottled gas and at this level combustion cannot be sustained. Oxygen concentration is monitored by instruments incorporated in an aspirating type of fire detector/alarm so that the operation of this system is automatic. T here can be provision to lower the oxygen concentration at night, when it is unlikely that the room need be visited, from the stated 16% by using the nitrogen generator.

Description

The present invention relates to an inerting method to reduce the risk and extinguish fires in ge closed rooms and a device for carrying out the Procedure.

It is known to be used indoors, which is only occasional be entered by humans or animals and their facilities react sensitively to the effects of water, there is the risk of fire by countering that the oxygen concentration in the be affected area to a value of on average about 12% is lowered. At this oxygen concentration, the most combustible materials no longer burn. Main entry Areas of application are IT areas, electrical switching and distribution rooms, enclosed facilities and storage areas with high quality economic goods. The right in this procedure resulting extinguishing effect is based on the principle of oxygen Displacement. The normal ambient air is known to exist 21% from oxygen, 78% from nitrogen and 1% from other against gases. Deletion is carried out by introducing a pure stick white the nitrogen concentration in the room in question ter increases and thus reduces the oxygen content. It is known to have an extinguishing effect when the oxygen proportion drops below 15 vol .-%. Depending on the in the be Existing combustible materials can hit a room further reducing the oxygen content to the above-mentioned 12 Vol .-% may be required.  

With this "inert gas extinguishing technology", as the flooding of a fire-endangered or fire-prone room is called by oxygen-displacing gases such as carbon dioxide, nitrogen, noble gases and mixtures thereof, the oxygen-displacing gases are usually stored compressed in steel cylinders in special adjoining rooms . If necessary, the gas is then piped into the room in question via pipe systems and corresponding outlet nozzles. However, extinguishing using inert gas technology poses certain problems and has clear limits with regard to the size of the room. For large rooms, for example with a floor area of 20.50 m and 6.5 m in height, the room volume is 6500 m ³ . As standard, steel bottles with a capacity of 80 l are used. In the case of inert gas extinguishing systems, these are filled with a pressure of 200 bar, which is currently the upper standard size due to the maximum load capacity of the fittings available. At a cylinder pressure of 200 bar, 80 l hold 18.3 kg nitrogen, for example, which then gives 16 m ³ nitrogen in the relaxed state at 1 bar ambient pressure. In order to flood the above-mentioned room with 6500 m ³ volume with inert gas, the content of 300 steel bottles would be required. Such a bottle weighs approx. 100 kg when filled, which would make a weight of 30 t for 300 bottles. In addition, there would be the weight of the pipes and fittings, so that very high demands would have to be placed on the load capacity of the storage rooms. In addition, a large footprint would be required for such a number of bottles. It is therefore clear that the inert gas extinguishing technology encounters problems of storage capacity and the load capacity of the storage rooms in larger rooms. Storing the bottles in a basement is also not a satisfactory solution, although the load-bearing capacity does not matter there. Long pipelines would have to be laid from the basement to the upper floors, which would mean additional construction work, which would often not be possible afterwards, and would also unduly extend the inflow time of the inert gas.

It was considered an object of the present invention to provide a Inerting process to reduce the risk of fire and to indicate how to extinguish fires in closed rooms, which is an effective extinguishing of a fire if possible ringer storage capacity for the inert gas cylinders.

This task is accomplished through an integration process The type mentioned above was solved with the following process steps: First, the oxygen content in the enclosed space to a certain basic level of inerting, for example 16% lowered, and in the event of a fire, the oxygen continue to a certain level of full inertization for example 12 vol .-% or less. A reason level of 16 vol .-% oxygen concentration meaning does not endanger people or animals, so that the can still enter the room easily. The Vollin The level of heating can either be set at night if no people or animals enter the room in question, or but directly in response to a reported fire. At 12 vol% Oxygen concentration is the flammability of mei Most materials already reduced so far that these can no longer ignite.

The advantages of the method according to the invention are in particular the fact that the number of containers required in the event of fire for the oxygen displacing inert gases significantly reduced becomes. This reduces the overall cost of fire prevention and fire extinguishing system considerably. Beyond that structurally a smaller pressure relief device is required, because in the event of a fire only a smaller gas volume within the short time available for that structural relief must be provided.

The above task is further accomplished by a Vorrich tion solved to carry out this procedure, initially has the following components: an oxygen measuring device in the room to be monitored; a first plant for the production of the Oxygen displacing gas or for the extraction of oxygen  from the room to be monitored; a second facility for sudden Chen introducing an oxygen displacing gas into the monitoring room; and a fire detection device for Detection of a fire parameter in the room air. To the solution a controller is provided for the task, which in Dependency of the oxygen content of the room air to be monitored a basic inerting signal to the first Plant for the production of the oxygen displacing gas or releases for the removal of oxygen, and that depending a detection signal from the fire detection device Outputs full inerting signal to the second system.

This device according to the invention realized in an ideal way se the connection of the inventive method with a Fire detection device. The control according to the invention Delivery of the basic inerting signal and the full inertia signal takes into account the special circumstances of the room to be monitored, its basic level of inertization according to the size and type of the room.

Advantageous further developments of the method are in the sub claims 2-9 specified, and to the device in the Claims 10-13.

Preferably, the inerting process contains the following a further 2 process steps, which take place before the 1st process step, lowering the oxygen content to a certain level Basic level of inertization to be carried out: After this The first step is the oxygen content in the monitoring room is measured and then done in a second Process step lowering to the basic inertization level depending on the measured oxygen value. So it fits the inerting process addresses certain leaks in the room by a classic regulation of the oxygen content in the room to be monitored.  

A detector for fire parameters is preferably inserted into the Process integrated, which signals a signal in the event of a fire Full inertization.

For example, the room air in the room to be monitored before lowering to a certain level of full inertization representative air samples taken continuously from a detector for fire parameters that are supplied in the event of a Si signals for full inerting. This training is the procedural implementation of the connection one known aspirative fire detection device with the inert gas extinguishing technology. This is under an aspirative branding understood a fire detection device, that via a pipeline or duct system on a variety a representative subset of the indoor air sucked in and this subset then a measuring chamber with a Detector for detecting a fire parameter supplied.

The term "fire parameter" includes physical parameters understood that measure in the area of an incipient fire changes, for example the environment temperature, the solid or liquid or gas content in the ambient air (formation of smoke in the form of particles or Aerosols or steam) or the ambient radiation.

The process can be carried out in a particularly advantageous manner lead if the basic level of inertization by machine Displace production and subsequent introduction of oxygen gases or by mechanical oxygen extraction me done. This is feasible in that it can be reduced to Basic inertization level more time is available, so that a gradual reduction in the oxygen content in the ent speaking space by a machine is sufficient. In contrast is for the rapid attainment of the full inerting level preferably introducing oxygen displacing gases provided in the enclosed space, whereby here in principle all inert gases can be used. These can be in front be provided in gas containers in part because  even in larger rooms, the volume to be filled between the Basic inertization level and the full inertization level no more problems. In addition, one mechanical production of oxygen displacing gases, for example by a nitrogen machine, of great size Advantage, because it also means the gas containers that are used for the Full inerting are responsible after use again can be filled.

Finally, it is preferably provided that the initiation of the Oxygen displacing gases depending on the in the ge closed room measured oxygen content takes place. Thereby is achieved that only for full inertization required amount of gas is supplied.

It has already been mentioned that one of the advantages of the invent The process according to the invention is to be seen in that it deals with the known fire detection devices can combine. At so-called aspirative fire detection devices is one constant control of the flow velocity of the suction representative partial air quantities required. According to one Further development of the device according to the invention is provided that the oxygen measuring device for performing the procedure rens in the detector housing of the fire detection device is integrated, where the air flow monitoring device is arranged.

Production of the oxygen is preferably displaced the gases to reach the basic level of inertia nell by a nitrogen machine or the like. It was already mentioned that this also advantageously for filled the full inertization responsible gas container once they have been emptied.

The method according to the invention is described below using a Flow chart explained in more detail.  

A closed room with normal room air is to be monitored with the usual oxygen content of 21% by volume. To the risk of a fire will reduce the oxygen content in the order closed space by introducing nitrogen from a Nitrogen machine to a certain basic level of inertization lowered. Before and simultaneously with the lowering to that The basic level of interest is the oxygen content in the monitoring room constantly measured. The target was on hand the properties of the room and its equipment with Computer equipment and the like calculated beforehand. An aspirative Fire detection device with a detector for fire characteristics, sucks through a pipe or Duct system constantly represent representative subsets of the room air and passes these subsets to the fire parameter detector to. If a fire parameter is detected and with the usual Security loops for a fire are recognized, so is the room quickly flooded with nitrogen from steel bottles until a ge desired oxygen concentration is reached. This was beforehand based on the flammable materia in the room lien determined.

As long as there is no fire, use the oxygen measuring device continuously checks whether a lower threshold of a ge hazardous oxygen concentration is reached. Is if this is not yet the case, the nitrogen machine continues to operate the basic inertization signal and floods the room further with nitrogen. Is the threshold value hazardous to health? is sufficient, a query is made as to whether the conditions for a night operation or the conditions for a day drive to be manufactured. Shouldn't the room through People or animals are entered, the full inertia signal to the nitrogen machine, whereupon in Another depending on the measured oxygen content Oxygen displacement takes place until that for the room and the materials contained therein specified extinguishable concentrations tration is reached. However, should the room still enter be, with the help of the oxygen measuring device  Oxygen concentration on a non-health hazard Value held at around 16%.

Claims (13)

1. Inerting procedure for reducing the risk and extinguishing fires in closed rooms, with the following procedural steps:

• a) the oxygen content in the enclosed space is reduced to a certain basic level of inertization; and
• b) in the event of a fire, the oxygen content is rapidly reduced further to a certain level of full inertization.

2. The method according to claim 1, characterized by the following additional method steps before method step a)

• a1) the oxygen content in the room to be monitored is measured;
• a2) the reduction to the basic inertization level takes place as a function of the measured oxygen value.

3. The method according to claim 1 or 2, characterized by the following further process step before process step b)

• b1) a detector for fire parameters emits a signal for full inertization in the event of a fire.

4. The method according to claim 1 or 2, characterized by the following further process step before process step b):

• b1) representative air samples are constantly taken from the room air in the room to be monitored, which are fed to a detector for fire parameters, which emits a signal for full inertization in the event of a fire.

5. The method according to any one of claims 1-4, characterized in that lowering and holding the desired basic inertia levels through production and / or initiation of Oxygen displacing gases takes place. 6. The method according to any one of claims 1-4, characterized in that lowering and holding the desired basic inertia levels of oxygenation he follows. 7. The method according to any one of claims 1-6, characterized in that the rapid further lowering of the oxygen content to the Full inertization level by introducing oxygen displacing gas in the enclosed space. 8. The method according to claim 7, characterized in that the oxygen displacing gas in gas containers is posed. 9. The method according to any one of claims 5-8, characterized in that introducing the oxygen displacing gases into Depends on the measured oxygen content.   10. Device for performing the method according to any one of claims 1-9, with
an oxygen measuring device in the room to be monitored;
a first plant for the production of the oxygen displacing gas or for the extraction of oxygen from the room to be monitored;
a second system for the sudden introduction of an oxygen displacing gas into the room to be monitored; and with
a fire detection device for detecting a fire parameter in the room air,
marked by
a controller which, depending on the oxygen content of the room air of the room to be monitored, emits a basic signaling signal to the first system and which, depending on a detection signal from the fire detection device, outputs a full inerting signal to the second system. 11. The device according to claim 10, characterized in that the fire detection device is an aspirative fire is identification device. 12. The device according to claim 11, characterized in that the oxygen measuring device in the detector housing Fire detection device is integrated. 13. The device according to one of claims 10-12, characterized in that the production of oxygen displacing gases for Reaching the basic level of inertia by machine, for example by a nitrogen machine.